/*---------------------------------------------------------------------------*\
  =========                 |
  \\      /  F ield         | OpenFOAM: The Open Source CFD Toolbox
   \\    /   O peration     | Website:  https://openfoam.org
    \\  /    A nd           | Copyright (C) 2012-2018 OpenFOAM Foundation
     \\/     M anipulation  |
-------------------------------------------------------------------------------
License
    This file is part of OpenFOAM.

    OpenFOAM is free software: you can redistribute it and/or modify it
    under the terms of the GNU General Public License as published by
    the Free Software Foundation, either version 3 of the License, or
    (at your option) any later version.

    OpenFOAM is distributed in the hope that it will be useful, but WITHOUT
    ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
    FITNESS FOR A PARTICULAR PURPOSE.  See the GNU General Public License
    for more details.

    You should have received a copy of the GNU General Public License
    along with OpenFOAM.  If not, see <http://www.gnu.org/licenses/>.

\*---------------------------------------------------------------------------*/

#include "autoDensity.H"
#include "addToRunTimeSelectionTable.H"

// * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * //

namespace Foam
{

// * * * * * * * * * * * * * * Static Data Members * * * * * * * * * * * * * //

defineTypeNameAndDebug(autoDensity, 0);
addToRunTimeSelectionTable
(
    initialPointsMethod,
    autoDensity,
    dictionary
);

// * * * * * * * * * * * * * Private Member Functions  * * * * * * * * * * * //

void Foam::autoDensity::writeOBJ
(
    const treeBoundBox& bb,
    fileName name
) const
{
    OFstream str(time().path()/name + ".obj");

    Pout<< "Writing " << str.name() << endl;

    pointField bbPoints(bb.points());

    forAll(bbPoints, i)
    {
        meshTools::writeOBJ(str, bbPoints[i]);
    }

    forAll(treeBoundBox::edges, i)
    {
        const edge& e = treeBoundBox::edges[i];

        str << "l " << e[0] + 1 << ' ' << e[1] + 1 << nl;
    }
}


bool Foam::autoDensity::combinedOverlaps(const treeBoundBox& box) const
{
    if (Pstream::parRun())
    {
        return
            decomposition().overlapsThisProcessor(box)
         || geometryToConformTo().overlaps(box);
    }

    return geometryToConformTo().overlaps(box);
}


bool Foam::autoDensity::combinedInside(const point& p) const
{
    if (Pstream::parRun())
    {
        return
            decomposition().positionOnThisProcessor(p)
         && geometryToConformTo().inside(p);
    }

    return geometryToConformTo().inside(p);
}


Foam::Field<bool> Foam::autoDensity::combinedWellInside
(
    const pointField& pts,
    const scalarField& sizes
) const
{
    if (!Pstream::parRun())
    {
        return geometryToConformTo().wellInside
        (
            pts,
            minimumSurfaceDistanceCoeffSqr_*sqr(sizes)
        );
    }

    Field<bool> inside(pts.size(), true);

    // Perform AND operation between testing the surfaces and the previous
    // field, i.e the parallel result, or in serial, with true.

    Field<bool> insideA
    (
        geometryToConformTo().wellInside
        (
            pts,
            minimumSurfaceDistanceCoeffSqr_*sqr(sizes)
        )
    );

    Field<bool> insideB
    (
        decomposition().positionOnThisProcessor(pts)
    );

    // inside = insideA && insideB;

    // Pout<< insideA << nl << insideB << endl;

    forAll(inside, i)
    {
        // if (inside[i] != (insideA[i] && insideB[i]))
        // {
        //     Pout<< i << " not equal " << " "
        //         << pts[i] << " " << sizes[i] << " "
        //         << insideA[i] << " "
        //         << insideB[i] << " "
        //         << inside[i]
        //         << endl;
        // }

        inside[i] = (insideA[i] && insideB[i]);
    }

    return inside;
}


bool Foam::autoDensity::combinedWellInside
(
    const point& p,
    scalar size
) const
{
    bool inside = true;

    if (Pstream::parRun())
    {
        inside = decomposition().positionOnThisProcessor(p);
    }

    // Perform AND operation between testing the surfaces and the previous
    // result, i.e the parallel result, or in serial, with true.
    inside =
        inside
     && geometryToConformTo().wellInside
        (
            p,
            minimumSurfaceDistanceCoeffSqr_*sqr(size)
        );

    return inside;
}


Foam::label Foam::autoDensity::recurseAndFill
(
    DynamicList<Vb::Point>& initialPoints,
    const treeBoundBox& bb,
    label levelLimit,
    word recursionName
) const
{
    label treeDepth = 0;

    for (direction i = 0; i < 8; i++)
    {
        treeBoundBox subBB = bb.subBbox(i);

        word newName = recursionName + "_" + Foam::name(i);

        conformalVoronoiMesh::timeCheck(time(), newName, debug);

        if (combinedOverlaps(subBB))
        {
            if (levelLimit > 0)
            {
                treeDepth =
                    max
                    (
                        treeDepth,
                        recurseAndFill
                        (
                            initialPoints,
                            subBB,
                            levelLimit - 1,
                            newName
                        )
                    );
            }
            else
            {
                if (debug)
                {
                    writeOBJ
                    (
                        subBB,
                        word(newName + "_overlap")
                    );

                    Pout<< newName + "_overlap " << subBB << endl;
                }

                if (!fillBox(initialPoints, subBB, true))
                {
                    treeDepth =
                        max
                        (
                            treeDepth,
                            recurseAndFill
                            (
                                initialPoints,
                                subBB,
                                levelLimit - 1,
                                newName
                            )
                        );
                }
            }
        }
        else if (combinedInside(subBB.midpoint()))
        {
            if (debug)
            {
                writeOBJ
                (
                    subBB,
                    newName + "_inside"
                );

                Pout<< newName + "_inside " << subBB << endl;
            }

            if (!fillBox(initialPoints, subBB, false))
            {
                treeDepth =
                    max
                    (
                        treeDepth,
                        recurseAndFill
                        (
                            initialPoints,
                            subBB,
                            levelLimit - 1,
                            newName
                        )
                    );
            }
        }
        else
        {
            if (debug)
            {
                writeOBJ
                (
                    subBB,
                    newName + "_outside"
                );
            }
        }
    }

    return treeDepth + 1;
}


bool Foam::autoDensity::fillBox
(
    DynamicList<Vb::Point>& initialPoints,
    const treeBoundBox& bb,
    bool overlapping
) const
{
    const conformationSurfaces& geometry = geometryToConformTo();

    label initialSize = initialPoints.size();

    scalar maxCellSize = -great;

    scalar minCellSize = great;

    scalar maxDensity = 1/pow3(minCellSize);

    scalar volumeAdded = 0.0;

    const point& min = bb.min();

    vector span = bb.span();

    scalar totalVolume = bb.volume();

    label trialPoints = 0;

    bool wellInside = false;

    if (!overlapping)
    {
        // Check the nearest point on the surface to the box, if it is far
        // enough away, then the surface sampling of the box can be skipped.
        // Checking if the nearest piece of surface is at least 1.5*bb.span away
        // from the bb.midpoint.

        pointIndexHit surfHit;
        label hitSurface;

        geometry.findSurfaceNearest
        (
            bb.midpoint(),
            2.25*magSqr(span),
            surfHit,
            hitSurface
        );

        if (!surfHit.hit())
        {
            if (debug)
            {
                Pout<< "box wellInside, no need to sample surface." << endl;
            }

            wellInside = true;
        }
    }

    if (!overlapping && !wellInside)
    {
        // If this is an inside box then it is possible to fill points very
        // close to the boundary, to prevent this, check the corners and sides
        // of the box so ensure that they are "wellInside".  If not, set as an
        // overlapping box.

        pointField corners(bb.points());

        scalarField cornerSizes = cellShapeControls().cellSize(corners);

        Field<bool> insideCorners = combinedWellInside(corners, cornerSizes);

        // Pout<< corners << nl << cornerSizes << nl << insideCorners << endl;

        forAll(insideCorners, i)
        {
            // Use the sizes to improve the min/max cell size estimate
            scalar s = cornerSizes[i];

            if (s > maxCellSize)
            {
                maxCellSize = s;
            }

            if (s < minCellSize)
            {
                minCellSize = max(s, minCellSizeLimit_);
            }

            if (maxCellSize/minCellSize > maxSizeRatio_)
            {
                if (debug)
                {
                    Pout<< "Abort fill at corner sample stage,"
                        << " minCellSize " << minCellSize
                        << " maxCellSize " << maxCellSize
                        << " maxSizeRatio " << maxCellSize/minCellSize
                        << endl;
                }

                return false;
            }

            if (!insideCorners[i])
            {
                // If one or more corners is not "wellInside", then treat this
                // as an overlapping box.

                if (debug)
                {
                    Pout<< "Inside box found to have some non-wellInside "
                        << "corners, using overlapping fill."
                        << endl;
                }

                overlapping = true;

                break;
            }
        }

        if (!overlapping)
        {
            vector delta = span/(surfRes_ - 1);

            label nLine = 6*(surfRes_ - 2);

            pointField linePoints(nLine, Zero);

            scalarField lineSizes(nLine, 0.0);

            for (label i = 0; i < surfRes_; i++)
            {
                label lPI = 0;

                for (label j = 1; j < surfRes_ - 1 ; j++)
                {
                    linePoints[lPI++] =
                        min
                      + vector(0, delta.y()*i, delta.z()*j);

                    linePoints[lPI++] =
                        min
                      + vector
                        (
                            delta.x()*(surfRes_ - 1),
                            delta.y()*i,
                            delta.z()*j
                        );

                    linePoints[lPI++] =
                        min
                      + vector(delta.x()*j, 0, delta.z()*i);

                    linePoints[lPI++] =
                        min
                      + vector
                        (
                            delta.x()*j,
                            delta.y()*(surfRes_ - 1),
                            delta.z()*i
                        );

                    linePoints[lPI++] =
                        min
                      + vector(delta.x()*i, delta.y()*j, 0);

                    linePoints[lPI++] =
                        min
                      + vector
                        (
                            delta.x()*i,
                            delta.y()*j,
                            delta.z()*(surfRes_ - 1)
                        );
                }

                lineSizes = cellShapeControls().cellSize(linePoints);

                Field<bool> insideLines = combinedWellInside
                (
                    linePoints,
                    lineSizes
                );

                forAll(insideLines, i)
                {
                    // Use the sizes to improve the min/max cell size estimate
                    scalar s = lineSizes[i];

                    if (s > maxCellSize)
                    {
                        maxCellSize = s;
                    }

                    if (s < minCellSize)
                    {
                        minCellSize = max(s, minCellSizeLimit_);
                    }

                    if (maxCellSize/minCellSize > maxSizeRatio_)
                    {
                        if (debug)
                        {
                            Pout<< "Abort fill at surface sample stage, "
                                << " minCellSize " << minCellSize
                                << " maxCellSize " << maxCellSize
                                << " maxSizeRatio " << maxCellSize/minCellSize
                                << endl;
                        }

                        return false;
                    }

                    if (!insideLines[i])
                    {
                        // If one or more surface points is not "wellInside",
                        // then treat this as an overlapping box.
                        overlapping = true;

                        if (debug)
                        {
                            Pout<< "Inside box found to have some non-"
                                << "wellInside surface points, using "
                                << "overlapping fill."
                                << endl;
                        }

                        break;
                    }
                }
            }
        }
    }

    if (overlapping)
    {
        // Sample the box to find an estimate of the min size, and a volume
        // estimate when overlapping == true.

        pointField samplePoints
        (
            volRes_*volRes_*volRes_,
            Zero
        );

        vector delta = span/volRes_;

        label pI = 0;

        for (label i = 0; i < volRes_; i++)
        {
            for (label j = 0; j < volRes_; j++)
            {
                for (label k = 0; k < volRes_; k++)
                {
                    // Perturb the points to avoid creating degenerate positions
                    // in the Delaunay tessellation.

                    samplePoints[pI++] =
                        min
                      + vector
                        (
                            delta.x()
                           *(i + 0.5 + 0.1*(rndGen().scalar01() - 0.5)),
                            delta.y()
                           *(j + 0.5 + 0.1*(rndGen().scalar01() - 0.5)),
                            delta.z()
                           *(k + 0.5 + 0.1*(rndGen().scalar01() - 0.5))
                        );
                }
            }
        }

        // Randomise the order of the points to (potentially) improve the speed
        // of assessing the density ratio, and prevent a box being filled from a
        // corner when only some these points are required.
        shuffle(samplePoints);

        scalarField sampleSizes = cellShapeControls().cellSize(samplePoints);

        Field<bool> insidePoints = combinedWellInside
        (
            samplePoints,
            sampleSizes
        );

        label nInside = 0;

        forAll(insidePoints, i)
        {
            if (insidePoints[i])
            {
                nInside++;

                scalar s = sampleSizes[i];

                if (s > maxCellSize)
                {
                    maxCellSize = s;
                }

                if (s < minCellSize)
                {
                    minCellSize = max(s, minCellSizeLimit_);
                }

                if (maxCellSize/minCellSize > maxSizeRatio_)
                {
                    if (debug)
                    {
                        Pout<< "Abort fill at sample stage,"
                            << " minCellSize " << minCellSize
                            << " maxCellSize " << maxCellSize
                            << " maxSizeRatio " << maxCellSize/minCellSize
                            << endl;
                    }

                    return false;
                }
            }
        }

        if (nInside == 0)
        {
            if (debug)
            {
                Pout<< "No sample points found inside box" << endl;
            }

            return true;
        }

        if (debug)
        {
            Pout<< scalar(nInside)/scalar(samplePoints.size())
                << " full overlapping box" << endl;
        }

        totalVolume *= scalar(nInside)/scalar(samplePoints.size());

        if (debug)
        {
            Pout<< "Total volume to fill = " << totalVolume << endl;
        }

        // Using the sampledPoints as the first test locations as they are
        // randomly shuffled, but unfiormly sampling space and have wellInside
        // and size data already

        maxDensity = 1/pow3(max(minCellSize, small));

        forAll(insidePoints, i)
        {
            if (insidePoints[i])
            {
                trialPoints++;

                const point& p = samplePoints[i];

                scalar localSize = sampleSizes[i];

                scalar localDensity = 1/pow3(localSize);

                // No need to look at max/min cell size here, already handled
                // by sampling

                // Accept possible placements proportional to the relative
                // local density

                // TODO - is there a lot of cost in the 1/density calc?  Could
                // assess on
                //    (1/maxDensity)/(1/localDensity) = minVolume/localVolume
                if (localDensity/maxDensity > rndGen().scalar01())
                {
                    scalar localVolume = 1/localDensity;

                    if (volumeAdded + localVolume > totalVolume)
                    {
                        // Add the final box with a probability of to the ratio
                        // of the remaining volume to the volume to be added,
                        // i.e. insert a box of volume 0.5 into a remaining
                        // volume of 0.1 20% of the time.
                        scalar addProbability =
                           (totalVolume - volumeAdded)/localVolume;

                        scalar r = rndGen().scalar01();

                        if (debug)
                        {
                            Pout<< "totalVolume " << totalVolume << nl
                                << "volumeAdded " << volumeAdded << nl
                                << "localVolume " << localVolume << nl
                                << "addProbability " << addProbability << nl
                                << "random " << r
                                << endl;
                        }

                        if (addProbability > r)
                        {
                            // Place this volume before finishing filling this
                            // box

                            // Pout<< "Final volume probability break accept"
                            //     << endl;

                            initialPoints.append
                            (
                                Vb::Point(p.x(), p.y(), p.z())
                            );

                            volumeAdded += localVolume;
                        }

                        break;
                    }

                    initialPoints.append(Vb::Point(p.x(), p.y(), p.z()));

                    volumeAdded += localVolume;
                }
            }
        }
    }

    if (volumeAdded < totalVolume)
    {
        if (debug)
        {
            Pout<< "Adding random points, remaining volume "
                << totalVolume - volumeAdded
                << endl;
        }

        maxDensity = 1/pow3(max(minCellSize, small));

        while (true)
        {
            trialPoints++;

            point p = min + cmptMultiply(span, rndGen().sample01<vector>());

            scalar localSize = cellShapeControls().cellSize(p);

            bool insidePoint = false;

            if (!overlapping)
            {
                insidePoint = true;
            }
            else
            {
                // Determine if the point is "wellInside" the domain
                insidePoint = combinedWellInside(p, localSize);
            }

            if (insidePoint)
            {
                if (localSize > maxCellSize)
                {
                    maxCellSize = localSize;
                }

                if (localSize < minCellSize)
                {
                    minCellSize = max(localSize, minCellSizeLimit_);

                    localSize = minCellSize;

                    // 1/(minimum cell size)^3, gives the maximum permissible
                    // point density
                    maxDensity = 1/pow3(max(minCellSize, small));
                }

                if (maxCellSize/minCellSize > maxSizeRatio_)
                {
                    if (debug)
                    {
                        Pout<< "Abort fill at random fill stage,"
                            << " minCellSize " << minCellSize
                            << " maxCellSize " << maxCellSize
                            << " maxSizeRatio " << maxCellSize/minCellSize
                            << endl;
                    }

                    // Discard any points already filled into this box by
                    // setting size of initialPoints back to its starting value
                    initialPoints.resize(initialSize);

                    return false;
                }

                scalar localDensity = 1/pow3(max(localSize, small));

                // Accept possible placements proportional to the relative local
                // density
                if (localDensity/maxDensity > rndGen().scalar01())
                {
                    scalar localVolume = 1/localDensity;

                    if (volumeAdded + localVolume > totalVolume)
                    {
                        // Add the final box with a probability of to the ratio
                        // of the remaining volume to the volume to be added,
                        // i.e. insert a box of volume 0.5 into a remaining
                        // volume of 0.1 20% of the time.
                        scalar addProbability =
                            (totalVolume - volumeAdded)/localVolume;

                        scalar r = rndGen().scalar01();

                        if (debug)
                        {
                            Pout<< "totalVolume " << totalVolume << nl
                                << "volumeAdded " << volumeAdded << nl
                                << "localVolume " << localVolume << nl
                                << "addProbability " << addProbability << nl
                                << "random " << r
                                << endl;
                        }

                        if (addProbability > r)
                        {
                            // Place this volume before finishing filling this
                            // box

                            // Pout<< "Final volume probability break accept"
                            //     << endl;

                            initialPoints.append
                            (
                                Vb::Point(p.x(), p.y(), p.z())
                            );

                            volumeAdded += localVolume;
                        }

                        break;
                    }

                    initialPoints.append(Vb::Point(p.x(), p.y(), p.z()));

                    volumeAdded += localVolume;
                }
            }
        }
    }

    globalTrialPoints_ += trialPoints;

    if (debug)
    {
        Pout<< trialPoints
            << " locations queried, " << initialPoints.size() - initialSize
            << " points placed, ("
            << scalar(initialPoints.size() - initialSize)
              /scalar(max(trialPoints, 1))
            << " success rate)." << nl
            << "minCellSize " << minCellSize
            << ", maxCellSize " << maxCellSize
            << ", ratio " << maxCellSize/minCellSize
            << nl << endl;
    }

    return true;
}


// * * * * * * * * * * * * * * * * Constructors  * * * * * * * * * * * * * * //

autoDensity::autoDensity
(
    const dictionary& initialPointsDict,
    const Time& runTime,
    Random& rndGen,
    const conformationSurfaces& geometryToConformTo,
    const cellShapeControl& cellShapeControls,
    const autoPtr<backgroundMeshDecomposition>& decomposition
)
:
    initialPointsMethod
    (
        typeName,
        initialPointsDict,
        runTime,
        rndGen,
        geometryToConformTo,
        cellShapeControls,
        decomposition
    ),
    globalTrialPoints_(0),
    minCellSizeLimit_
    (
        detailsDict().lookupOrDefault<scalar>("minCellSizeLimit", 0.0)
    ),
    minLevels_(readLabel(detailsDict().lookup("minLevels"))),
    maxSizeRatio_(readScalar(detailsDict().lookup("maxSizeRatio"))),
    volRes_(readLabel(detailsDict().lookup("sampleResolution"))),
    surfRes_
    (
        detailsDict().lookupOrDefault<label>("surfaceSampleResolution", volRes_)
    )
{
    if (maxSizeRatio_ <= 1.0)
    {
        maxSizeRatio_ = 2.0;

        WarningInFunction
            << "The maxSizeRatio must be greater than one to be sensible, "
            << "setting to " << maxSizeRatio_
            << endl;
    }
}


// * * * * * * * * * * * * * * * Member Functions  * * * * * * * * * * * * * //

List<Vb::Point> autoDensity::initialPoints() const
{
    treeBoundBox hierBB;

    // Pick up the bounds of this processor, or the whole geometry, depending
    // on whether this is a parallel run.
    if (Pstream::parRun())
    {
        hierBB = decomposition().procBounds();
    }
    else
    {
        // Extend the global box to move it off large plane surfaces
        hierBB = geometryToConformTo().globalBounds().extend(1e-6);
    }

    DynamicList<Vb::Point> initialPoints;

    Info<< nl << "    " << typeName << endl;

    if (debug)
    {
        Pout<< "    Filling box " << hierBB << endl;
    }

    label treeDepth = recurseAndFill
    (
        initialPoints,
        hierBB,
        minLevels_ - 1,
        "recursionBox"
    );

    initialPoints.shrink();

    label nInitialPoints = initialPoints.size();

    if (Pstream::parRun())
    {
        reduce(nInitialPoints, sumOp<label>());
        reduce(globalTrialPoints_, sumOp<label>());
    }

    Info<< incrIndent << incrIndent
        << indent << nInitialPoints << " points placed" << nl
        << indent << globalTrialPoints_ << " locations queried" << nl
        << indent
        << scalar(nInitialPoints)/scalar(max(globalTrialPoints_, 1))
        << " success rate" << nl
        << indent
        << returnReduce(treeDepth, maxOp<label>())
        << " levels of recursion (maximum)"
        << decrIndent << decrIndent
        << endl;

    return initialPoints;
}


// * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * //

} // End namespace Foam

// ************************************************************************* //
